data declaration, a type constructor is the thing on the left hand side of the equals sign. The data constructor(s) are the things on the right hand side of the equals sign. You use type constructors where a type is expected, and you use data constructors where a value is expected.
To make things simple, we can start with an example of a type that represents a colour.
data Colour = Red | Green | Blue
Here, we have three data constructors.
Colour is a type, and
Green is a constructor that contains a value of type
Blue are both constructors that construct values of type
Colour. We could imagine spicing it up though!
data Colour = RGB Int Int Int
We still have just the type
RGB is not a value – it's a function taking three ints and returning a value!
RGB has the type
RGB :: Int -> Int -> Int -> Colour
RGB is a data constructor that is a function taking some values as its arguments, and then uses those to construct a new value. If you have done any object-oriented programming, you should recognise this. In OOP, constructors also take some values as arguments and return a new value!
In this case, if we apply
RGB to three values, we get a colour value!
Prelude> RGB 12 92 27
We have constructed a value of type
Colour by applying the data constructor. A data constructor either contains a value like a variable would, or takes other values as its argument and creates a new value. If you have done previous programming, this concept shouldn't be very strange to you.
If you'd want to construct a binary tree to store
Strings, you could imagine doing something like
data SBTree = Leaf String
| Branch String SBTree SBTree
What we see here is a type
SBTree that contains two data constructors. In other words, there are two functions (namely
Branch) that will construct values of the
SBTree type. If you're not familiar with how binary trees work, just hang in there. You don't actually need to know how binary trees work, only that this one stores
Strings in some way.
We also see that both data constructors take a
String argument – this is the String they are going to store in the tree.
But! What if we also wanted to be able to store
Bool, we'd have to create a new binary tree. It could look something like this:
data BBTree = Leaf Bool
| Branch Bool BBTree BBTree
BBTree are type constructors. But there's a glaring problem. Do you see how similar they are? That's a sign that you really want a parameter somewhere.
So we can do this:
data BTree a = Leaf a
| Branch a (BTree a) (BTree a)
Now we introduce a type variable
a as a parameter to the type constructor. In this declaration,
BTree has become a function. It takes a type as its argument and it returns a new type.
It is important here to consider the difference between a concrete type (examples include
Maybe Bool) which is a type that can be assigned to a value in your program, and a type constructor function which you need to feed a type to be able to be assigned to a value. A value can never be of type "list", because it needs to be a "list of something". In the same spirit, a value can never be of type "binary tree", because it needs to be a "binary tree storing something".
If we pass in, say,
Bool as an argument to
BTree, it returns the type
BTree Bool, which is a binary tree that stores
Bools. Replace every occurrence of the type variable
a with the type
Bool, and you can see for yourself how it's true.
If you want to, you can view
BTree as a function with the kind
BTree :: * -> *
Kinds are somewhat like types – the
* indicates a concrete type, so we say
BTree is from a concrete type to a concrete type.
Step back here a moment and take note of the similarities.
Data constructors with parameters are cool if we want slight variations in our values – we put those variations in parameters and let the guy who creates the value decide what arguments they are going to put in. In the same sense, type constructors with parameters are cool if we want slight variations in our types! We put those variations as parameters and let the guy who creates the type decide what arguments they are going to put in.
A case study
As the home stretch here, we can consider the
Maybe a type. It's definition is
data Maybe a = Nothing
| Just a
Maybe is a type constructor that returns a concrete type.
Just is a data constructor that returns a value.
Nothing is a data constructor that contains a value. If we look at the type of
Just, we see that
Just :: a -> Maybe a
In other words,
Just takes a value of type
a and returns a value of type
Maybe a. If we look at the kind of
Maybe, we see that
Maybe :: * -> *
In other words,
Maybe takes a concrete type and returns a concrete type.
Once again! The difference between a concrete type and a type constructor function. You can not create a list of
Maybes. If you try to execute
 :: [Maybe]
you'll get an error. You can however create a list of
Maybe Int, or
Maybe a. That's because
Maybe is a type constructor function, but a list needs to contain values of a concrete type.
Maybe Int and
Maybe a are concrete types (or if you want, calls to type constructor functions that return concrete types.)